src/storage/minfs/allocator/inode_manager.cc - fuchsia - Git at Google

 // Copyright 2018 The Fuchsia Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "src/storage/minfs/allocator/inode_manager.h"

 #include <stdlib.h>

 #include <memory>

 #include <storage/buffer/block_buffer.h>

 #include "src/storage/minfs/format.h"
 #include "src/storage/minfs/unowned_vmo_buffer.h"

 namespace minfs {

 InodeManager::InodeManager(blk_t start_block, uint32_t block_size)
     : start_block_(start_block), block_size_(block_size) {}

 zx_status_t InodeManager::Create(block_client::BlockDevice* device, SuperblockManager* sb,
                                  fs::BufferedOperationsBuilder* builder, AllocatorMetadata metadata,
                                  blk_t start_block, size_t inodes,
                                  std::unique_ptr<InodeManager>* out) {
   auto mgr = std::unique_ptr<InodeManager>(new InodeManager(start_block, sb->BlockSize()));
   InodeManager* mgr_raw = mgr.get();

   auto grow_cb = [mgr_raw](uint32_t pool_size) { return mgr_raw->Grow(pool_size); };

   zx_status_t status;
   std::unique_ptr<PersistentStorage> storage(new PersistentStorage(
       device, sb, kMinfsInodeSize, std::move(grow_cb), std::move(metadata), sb->BlockSize()));

   if ((status = Allocator::Create(builder, std::move(storage), &mgr->inode_allocator_)) != ZX_OK) {
     return status;
   }

   uint32_t inoblks =
       (static_cast<uint32_t>(inodes) + kMinfsInodesPerBlock - 1) / kMinfsInodesPerBlock;
   if ((status = mgr->inode_table_.CreateAndMap(inoblks * sb->BlockSize(), "minfs-inode-table")) !=
       ZX_OK) {
     return status;
   }

   storage::Vmoid vmoid;
   status = device->BlockAttachVmo(mgr->inode_table_.vmo(), &vmoid);
   if (status != ZX_OK) {
     return status;
   }
   vmoid_t id = vmoid.get();
   builder->AddVmoid(storage::OwnedVmoid(std::move(vmoid), device));

   storage::Operation operation{
       .type = storage::OperationType::kRead,
       .vmo_offset = 0,
       .dev_offset = start_block,
       .length = inoblks,
   };

   fs::internal::BorrowedBuffer buffer(id);
   builder->Add(operation, &buffer);

   *out = std::move(mgr);
   return ZX_OK;
 }

 void InodeManager::Update(PendingWork* transaction, ino_t ino, const Inode* inode) {
   // Obtain the offset of the inode within its containing block.
   const uint32_t off_of_ino = (ino % kMinfsInodesPerBlock) * kMinfsInodeSize;
   const blk_t inoblock_rel = ino / kMinfsInodesPerBlock;
   const blk_t inoblock_abs = inoblock_rel + start_block_;
   ZX_DEBUG_ASSERT(inoblock_abs < kFVMBlockDataStart);

   char* inodata = reinterpret_cast<char*>(inode_table_.start()) + inoblock_rel * BlockSize();
   memcpy(inodata + off_of_ino, inode, kMinfsInodeSize);

   storage::Operation operation = {
       .type = storage::OperationType::kWrite,
       .vmo_offset = inoblock_rel,
       .dev_offset = inoblock_abs,
       .length = 1,
   };
   UnownedVmoBuffer buffer(zx::unowned_vmo(inode_table_.vmo()));
   transaction->EnqueueMetadata(operation, &buffer);
 }

 const Allocator* InodeManager::GetInodeAllocator() const { return inode_allocator_.get(); }

 void InodeManager::Load(ino_t ino, Inode* out) const {
   // Obtain the block of the inode table we need.
   uint32_t off_of_ino = (ino % kMinfsInodesPerBlock) * kMinfsInodeSize;
   const char* inodata = reinterpret_cast<const char*>(inode_table_.start()) +
                         ino / kMinfsInodesPerBlock * BlockSize();
   const Inode* inode = reinterpret_cast<const Inode*>(inodata + off_of_ino);
   memcpy(out, inode, kMinfsInodeSize);
 }

 zx_status_t InodeManager::Grow(size_t inodes) {
   uint32_t inoblks =
       (static_cast<uint32_t>(inodes) + kMinfsInodesPerBlock - 1) / kMinfsInodesPerBlock;
   if (inode_table_.Grow(inoblks * BlockSize()) != ZX_OK) {
     return ZX_ERR_NO_SPACE;
   }
   return ZX_OK;
 }

 }  // namespace minfs
	// Copyright 2018 The Fuchsia Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "src/storage/minfs/allocator/inode_manager.h"

	#include <stdlib.h>

	#include <memory>

	#include <storage/buffer/block_buffer.h>

	#include "src/storage/minfs/format.h"
	#include "src/storage/minfs/unowned_vmo_buffer.h"

	namespace minfs {

	InodeManager::InodeManager(blk_t start_block, uint32_t block_size)
	: start_block_(start_block), block_size_(block_size) {}

	zx_status_t InodeManager::Create(block_client::BlockDevice* device, SuperblockManager* sb,
	fs::BufferedOperationsBuilder* builder, AllocatorMetadata metadata,
	blk_t start_block, size_t inodes,
	std::unique_ptr<InodeManager>* out) {
	auto mgr = std::unique_ptr<InodeManager>(new InodeManager(start_block, sb->BlockSize()));
	InodeManager* mgr_raw = mgr.get();

	auto grow_cb = [mgr_raw](uint32_t pool_size) { return mgr_raw->Grow(pool_size); };

	zx_status_t status;
	std::unique_ptr<PersistentStorage> storage(new PersistentStorage(
	device, sb, kMinfsInodeSize, std::move(grow_cb), std::move(metadata), sb->BlockSize()));

	if ((status = Allocator::Create(builder, std::move(storage), &mgr->inode_allocator_)) != ZX_OK) {
	return status;
	}

	uint32_t inoblks =
	(static_cast<uint32_t>(inodes) + kMinfsInodesPerBlock - 1) / kMinfsInodesPerBlock;
	if ((status = mgr->inode_table_.CreateAndMap(inoblks * sb->BlockSize(), "minfs-inode-table")) !=
	ZX_OK) {
	return status;
	}

	storage::Vmoid vmoid;
	status = device->BlockAttachVmo(mgr->inode_table_.vmo(), &vmoid);
	if (status != ZX_OK) {
	return status;
	}
	vmoid_t id = vmoid.get();
	builder->AddVmoid(storage::OwnedVmoid(std::move(vmoid), device));

	storage::Operation operation{
	.type = storage::OperationType::kRead,
	.vmo_offset = 0,
	.dev_offset = start_block,
	.length = inoblks,
	};

	fs::internal::BorrowedBuffer buffer(id);
	builder->Add(operation, &buffer);

	*out = std::move(mgr);
	return ZX_OK;
	}

	void InodeManager::Update(PendingWork* transaction, ino_t ino, const Inode* inode) {
	// Obtain the offset of the inode within its containing block.
	const uint32_t off_of_ino = (ino % kMinfsInodesPerBlock) * kMinfsInodeSize;
	const blk_t inoblock_rel = ino / kMinfsInodesPerBlock;
	const blk_t inoblock_abs = inoblock_rel + start_block_;
	ZX_DEBUG_ASSERT(inoblock_abs < kFVMBlockDataStart);

	char* inodata = reinterpret_cast<char>(inode_table_.start()) + inoblock_rel BlockSize();
	memcpy(inodata + off_of_ino, inode, kMinfsInodeSize);

	storage::Operation operation = {
	.type = storage::OperationType::kWrite,
	.vmo_offset = inoblock_rel,
	.dev_offset = inoblock_abs,
	.length = 1,
	};
	UnownedVmoBuffer buffer(zx::unowned_vmo(inode_table_.vmo()));
	transaction->EnqueueMetadata(operation, &buffer);
	}

	const Allocator* InodeManager::GetInodeAllocator() const { return inode_allocator_.get(); }

	void InodeManager::Load(ino_t ino, Inode* out) const {
	// Obtain the block of the inode table we need.
	uint32_t off_of_ino = (ino % kMinfsInodesPerBlock) * kMinfsInodeSize;
	const char* inodata = reinterpret_cast<const char*>(inode_table_.start()) +
	ino / kMinfsInodesPerBlock * BlockSize();
	const Inode* inode = reinterpret_cast<const Inode*>(inodata + off_of_ino);
	memcpy(out, inode, kMinfsInodeSize);
	}

	zx_status_t InodeManager::Grow(size_t inodes) {
	uint32_t inoblks =
	(static_cast<uint32_t>(inodes) + kMinfsInodesPerBlock - 1) / kMinfsInodesPerBlock;
	if (inode_table_.Grow(inoblks * BlockSize()) != ZX_OK) {
	return ZX_ERR_NO_SPACE;
	}
	return ZX_OK;
	}

	} // namespace minfs